A 4D printed active compliant hinge for potential space applications using shape memory alloys and polymers

Testoni, Oleg; Lumpe, Thomas S.; Huang, Jian-Lin; Wagner, Marius; Bodkhe, Sampada; Zhakypov, Zhenishbek; Spolenak, Ralph; Paik, Jamie; Ermanni, Paolo; Muñoz, Luis; Shea, Kristina

doi:10.1088/1361-665x/ac01fa

Cited by 24 publications

(14 citation statements)

References 41 publications

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“…A solar tracker actuation concept combining shape memory alloy springs and a polymer has also been tested. [ 31 ] Skins for self‐regulating buildings have also significant potential for applications as well. [ 32,33 ] However, recent developments of 4D‐printed actuators are mostly dominated by heat‐stimulated structures.…”

Section: Introductionmentioning

confidence: 99%

The Design of 4D‐Printed Hygromorphs: State‐of‐the‐Art and Future Challenges

Kergariou

Demoly

Perriman

et al. 2022

Adv Funct Materials

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In recent years, 4D printing has allowed the rapid development of new concepts of multifunctional/adaptive structures. The 4D printing technology makes it possible to generate new shapes and/or property-changing capabilities by combining smart materials, multiphysics stimuli, and additive manufacturing. Hygromorphs constitute a specific class of new smart materials where their properties and morphing capabilities are dependent on the surrounding humidity, which drives actuation. Although multiple efforts have been made to fabricate hygromorph demonstrators, a comprehensive design process to produce hygromorphs by multiple 4D printing techniques is not yet available. The broad aim of this review and concept paper is to i) highlight existing scientific and technology gaps in the field of 4D-printed hygromorphs, ii) identify tools existing in other research fields for filling those gaps, and iii) discuss a series of guidelines for tackling future challenges and opportunities to develop 4D-printed composite hygromorph materials and related manufacturing processes. Accordingly, this review describes the materials and additive manufacturing techniques used for hygromorph composite fabrication. Moreover, the relevant parameters that control actuation, the models selection and performance, the design methods and the actuation measurements for customized 4D-printed hygromorph materials, are discussed.

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Section: Introductionmentioning

confidence: 99%

The Design of 4D‐Printed Hygromorphs: State‐of‐the‐Art and Future Challenges

Kergariou

Demoly

Perriman

et al. 2022

Adv Funct Materials

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“…Therefore, the use of a clean energy source that can provide real-time power to these types of electronic devices has great market value and social benefits. Harvesting energy from the environment to wirelessly charge such electronic devices directly is one of the effective ways, including solar energy, [3,4] fluid, [5,6] mechanical operations, [7,8] human [9,10] and animal [11] activities, etc. A large number of energy conversion devices and technologies have been researched today to harvest energy from these environments, including thermoelectric, [12,13] electrostatic, [14,15] triboelectric nanogenerator, [16,17] and piezoelectric.…”

Section: Introductionmentioning

confidence: 99%

Experiments and Analysis of a Nonlinear Sickle‐Shaped Cantilever Beam Piezoelectric Energy Harvester for Wind Energy Harvesting

Wang

et al. 2022

Physica Status Solidi (a)

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Achieving broadband energy harvesting at low frequencies is a difficult area of research today. To solve the aforementioned problems, herein, a nonlinear sickle‐shaped cantilever beam piezoelectric energy harvester (S‐PEH) for wind energy harvesting is proposed. It has a high‐voltage output in the wind speed range of 5.37–18.23 m s−1. The S‐PEH is consists of a collector and a transducer. The collector converts wind energy into rotating mechanical energy and excites the transducer by means of magnetic coupling, thus realizing the conversion of mechanical energy to electrical energy. The special structure of the transducer's sickle‐shaped cantilever beam type can effectively harvest wind energy in low‐frequency environment and broaden the range of harvesting wind speed in high voltage. The structure and principle of S‐PEH are analyzed by theory and simulation and are experimentally verified. The results show that when the magnet on the rotor is 15 mm away from the magnet of the piezoelectric sheet, the transducer angle is 90°, the load resistance is 100 kΩ, the voltage of the blower is kept at 120 V, and the system has a maximum power of 563 μW. Moreover, it can successfully make low‐power electronics work.

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“…SMPs are particularly promising for the realization of monolithic reconfigurable structures with no bulky powered driving mechanisms and have already found applications in deployable booms (Roh et al, 2014), reconfigurable antennas (Santo et al, 2016) and hinges (Liu et al, 2018). However, so far SMPs have been mostly used for deployable structures with only one time actuation (Chen and Shea, 2018) and only few studies investigated their combination with SMA and multiple actuations (Testoni et al, 2021; Wang and Ahn, 2017).…”

Section: Introductionmentioning

confidence: 99%

Network of selectively compliant actuators based on shape memory alloys and polymers for a reconfigurable sandwich panel

Testoni

Bodkhe

Bergamini

et al. 2022

Journal of Intelligent Material Systems and Structures

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Shape memory alloys (SMA) allow for the realization of smart actuators capable of achieving large stresses and large strains but highly demanding in terms of power input. This work presents a solution integrating shape memory polymers (SMP) in a novel type of selectively compliant actuator to reduce the power input of SMAs. The thermally induced variation in stiffness of the SMP is used to achieve large deformations by temporarily increasing the compliance of the actuator and to lock the actuator in a deformed state by restoring the initial stiffness. The behavior of the actuator is simulated taking into account the viscoelastic behavior of the SMP and validated through a comparison with experimental results. The latter show that the proposed actuator can achieve a maximum contraction of 3.0% and hold a contraction of about 1.6% multiple times without constantly powering the SMA. Finally, a reconfigurable sandwich panel is considered as possible application. A distributed actuator network is implemented in the face sheets of the panel and a digital image correlation system is used to prove the capability of the proposed structure of undergoing large deformations, holding a deformed shape without consuming energy, and recovering its initial shape. A further development of this panel might find application as support structure for morphing aerodynamic surfaces or reconfigurable antennas.

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A 4D printed active compliant hinge for potential space applications using shape memory alloys and polymers

Cited by 24 publications

References 41 publications

The Design of 4D‐Printed Hygromorphs: State‐of‐the‐Art and Future Challenges

The Design of 4D‐Printed Hygromorphs: State‐of‐the‐Art and Future Challenges

Experiments and Analysis of a Nonlinear Sickle‐Shaped Cantilever Beam Piezoelectric Energy Harvester for Wind Energy Harvesting

Network of selectively compliant actuators based on shape memory alloys and polymers for a reconfigurable sandwich panel

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